Exploring Piezo1, Piezo2, and TMEM150C in human brain tissues and their correlation with brain biomechanical characteristics

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Arjun Raha, Yuning Wu, Lily Zhong, Jatheeshan Raveenthiran, Minji Hong, Aftab Taiyab, Li Wang, Bill Wang, Fei Geng
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Abstract

Unraveling the intricate relationship between mechanical factors and brain activity is a pivotal endeavor, yet the underlying mechanistic model of signaling pathways in brain mechanotransduction remains enigmatic. To bridge this gap, we introduced an in situ multi-scale platform, through which we delineate comprehensive brain biomechanical traits in white matter (WM), grey-white matter junctions (GW junction), and the pons across human brain tissue from four distinct donors. We investigate the three-dimensional expression patterns of Piezo1, Piezo2, and TMEM150C, while also examining their associated histological features and mechanotransduction signaling networks, particularly focusing on the YAP/β-catenin axis. Our results showed that the biomechanical characteristics (including stiffness, spring term, and equilibrium stress) associated with Piezo1 vary depending on the specific region. Moving beyond Piezo1, our result demonstrated the significant positive correlations between Piezo2 expression and stiffness in the WM. Meanwhile, the expression of Piezo2 and TMEM150C was shown to be correlated to viscoelastic properties in the pons and WM. Given the heterogeneity of brain tissue, we investigated the three-dimensional expression of Piezo1, Piezo2, and TMEM150C. Our results suggested that three mechanosensitive proteins remained consistent across different vertical planes within the tissue sections. Our findings not only establish Piezo1, Piezo2, and TMEM150C as pivotal mechanosensors that regulate the region-specific mechanotransduction activities but also unveil the paradigm connecting brain mechanical properties and mechanotransduction activities and the variations between individuals.
探索人脑组织中的 Piezo1、Piezo2 和 TMEM150C 及其与脑生物力学特征的相关性
揭示机械因素与大脑活动之间错综复杂的关系是一项至关重要的工作,然而大脑机械传导信号通路的基本机制模型仍然是个谜。为了弥合这一差距,我们引入了一个原位多尺度平台,通过该平台,我们在白质(WM)、灰白质交界处(GW交界处)和脑桥上对来自四个不同供体的人脑组织进行了全面的大脑生物力学特征描述。我们研究了 Piezo1、Piezo2 和 TMEM150C 的三维表达模式,同时还考察了它们的相关组织学特征和机械传导信号网络,尤其关注 YAP/β-catenin 轴。我们的研究结果表明,与 Piezo1 相关的生物力学特征(包括硬度、弹簧项和平衡应力)因具体区域而异。除了 Piezo1 之外,我们的结果还表明,Piezo2 的表达与 WM 中的僵硬度之间存在显著的正相关。同时,Piezo2 和 TMEM150C 的表达与脑桥和 WM 的粘弹性相关。鉴于脑组织的异质性,我们研究了 Piezo1、Piezo2 和 TMEM150C 的三维表达。我们的结果表明,三种机械敏感蛋白在组织切片的不同垂直平面上保持一致。我们的发现不仅确定了 Piezo1、Piezo2 和 TMEM150C 是调控特定区域机械传导活动的关键机械传感器,而且揭示了大脑机械特性和机械传导活动之间的联系范式以及个体之间的差异。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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